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.'
11176-H314-RO-OO
APOLLO 10
LM-4
DESCENT PROPULSION SYSTEM
FINAL FLIGHT EVALUATION
PROJECT TECHNICAL REPORT
Prepared byR. K. M. Seto
Propulsion Technology SectionPower Systems Department
CJ4 S ~ 8 AUGUST 1969
Prepared for Cop\Jl"~NATIONAL AERONAUTICS AND SPACE ADMINISTRATION j[ .
MANNED SPACECRAFT CENTERHOUSTON, TEXAS
NAS 9-8166
TRW--
NAS 9-8166
11176-H314-RO-OO
PROJECT TECHNICAL REPORT
APOLLO 10
LM-4
DESCENT PROPULSION SYSTEM
FINAL FLIGHT EVALUATION
8 AUGUST 1969
Prepared forNATIONAL AERONAUTICS AND SPACE ADMINISTRATION
MANNED SPACECRAFT CENTERHOUSTON, TEXAS
Prepared byR. K. M. Seto
Propulsion Technology SectionPower Systems Department
Approved by:
Approved by:
Approved by: .k'~ ~//!'J~R~r:~Manag~Task E-19E
TRW--
CONTENTS
PAGE1- PURPOSE AND SCOPE 1
2. SLMMARY . . . . . 2
3. INTRODUCTION . . . . 4
4. PERFORMANCE ANALYSIS 6
Descent Orbit Insertion Burn . . 7
Phas i ng Burn . . . . . . . . . 8
5. PRESSURIZATION SYSTEM EVALUATION . 9
6. PQGS EVALUATION AND PROPELLANT LOADING 11
7. ENGINE TRANSIENT ANALYSIS . . . . . . . . 14
Start and Shutdown Transients . . . . . . 14
Throttle Response 16
8. REFERENCES 17
ii
1. DPS MISSION DUTY CYCLE
TABLES
PAGE18
2. LM-4 DPS ENGINE AND FEED SYSTEM PHYSICAL CHARACTERISTICS 19
3. DESCENT PROPULSION SYSTEM FLIGHT DATA . . . . . . 20
4. DESCENT PROPULSION SYSTEM STEADY STATE PERFORMANCE -PHASING BURN . . . . . . . . . . 21
5. DPS PROPELLANT QUANTITY GAGING SYSTEM PERFORMANCE -END OF PHASING BURN . . . . . . 22
6. DPS START AND SHUTDOWN IMPULSE SUMMARY . . . . . . 23
iii
FIGURE NO.
1
2
3
4
5
6
7
8
9
ILLUSTRATIONS
MEASURED SUPERCRITICAL HELIUM TANK PRESSURE -PHASING BURN . . . . . . . . . . . .
MEASURED HELIUM REGULATOR OUTLET PRESSURE (GQ3018P)PHASING BURN • . . . . . . . . . . .
MEASURED OXIDIZER INTERFACE PRESSURE - PHASING BURN
MEASURED FUEL INTERFACE PRESSURE - PHASING BURN
MEASURED CHAMBER PRESSURE - PHASING BURN . . .
MEASURED PROPELLANT QUANTITY, OXIDIZER TANK NO.1PHASING BURN • . • . . . . . • . . .
MEASURED PROPELLANT QUANTITY, OXIDIZER TANK NO.2PHAS ING BURN . . . • • . • • • •
MEASURED PROPELLANT QUANTITY, FUEL TANK NO.1 -PHASING BURN . . . . . . . . . .
MEASURED PROPELLANT QUANTITY, FUEL TANK NO.2 -PHASING BURN . . . . . . . . . .
iv
PAGE
24
25
26
27
28
29
30
31
32
1. PURPOSE AND SCOPE
The purpose of this report is to present the results of the postflight
analysis of the Descent Propulsion System (OPS) performance during the
Apollo 10 Mission. This report documents additional analysis of the DPS.
Preliminary findings were reported in Reference 1. This report also brings
together information from other reports and memorandums analyzing specific
anomalies and performance in order to present a comprehensive description
of the OPS operation during Apollo 10.
The following items are the major additions to the results as reported
in Reference 1:
1) The performance for the second (Phasing) OPS burn;s discussed in greater detail.
2) The Pressurization System performance is revised.
3) The Propellant Quantity Gaging System performance is discussed in greater detail.
4) The transient performance analysis for DPS operation isexpanded.
2. SlJt1MARY
The performance of the LM-4 Descent Propulsion System during the
Apollo 10 Mission was evaluated and found to be satisfactory.
Because system data during the DOl maneuver was not recorded and due
to the short length of burns, no detailed performance study using the
Apollo Propulsion Analysis Program was possible. HOwever, the preflight
model was used with flight data to approximate the performance at repre
sentative times during the Phasing Burn. For minimum throttle operation,
(13.1% of full thrust) thrust, specific impulse, and mixture ratio were
calculated to be 1371 lbf, 296.5 seconds and 1.605, respectively. For FTP,
the values were 9841 lbf, 304.0 seconds and 1.599. These values can be
considered as representative only.
Instrumentation biases were determined on the regulator outlet pres
sure measurement (GQ3018P), the oxidizer interface pressure measurement
and the chamber pressure measurement with values of +4.0, +7.5,and -0.8 to
-1.6 psi, respectively.
The supercritical helium tank experienced an average pressure rise
rate of 5.84 psi/hr during the coast period between launch and first DPS
engine firing. This value was less than anticipated from ground tests.
Although the fuel quantity gages (Fu 1 and Fu 2) never read off scale
(greater than the maximum 95 percent indication) as expected prior to the
Phasing Burn, they did respond with propellant consumption and were within
both the expected accuracy of 3.5% and the specification limits of 1.3%
at the end of the burn. The oxidizer gages (Ox 1 and Ox 2) operated as
expected prior to the phasing burn. However, at the end of the burn, it
appeared that the Ox 2 gage was reading 1.6% higher than expected. This
reading was still within the expected accuracy of 2.7%.
2
The engine start and snutdown tran5ient~ compared very well with
predicted values. The shutdown transient time, however, was 0.09 seconds
greater than the specification limit of 0.25 seconds. The throttle response
from 13.1% to FTP was acceptable.
3
3. INTRODUCTION
The Apollo 10 Mission was the tenth in a series of flights using speci
fication Apollo hardware. It was the third flight test and the second
manned flight of the lunar Module (lM). The mission was the fourth manned
flight of Block II Command and Service Module (CSM) and the third manned
flight using a Saturn V launch vehicle.
The overall mission objectivel was to duplicate, as closely as possible,
a G type mission with the exception of lunar landing and liftoff. This
included the performance of the Descent Orbit Insertion maneuver by the
Descent Propulsion System (DPS) and the rendezvous maneuvers by the Ascent
Propulsion System (APS). Also included as objectives were to verify lM
operation in a lunar environment, verify mission support of all spacecrafts
during all mission phases at lunar distances and to obtain more information
about the lunar potential.
The space vehicle was launched from the Kennedy Space Center (KSC) at
12:49:00 P.M. (EST) on May 18, 1969. Following a normal launch phase, the
S-IVB stage inserted the spacecraft into an orbit of 102.6 by 99.6 nautical
miles. Two and a half hours after launch the S-IVB performed the trans
lunar injection maneuver. The CSM docked with the lM and the docked space
crafts were ejected from the S-IVB approximately four hours after launch.
During the next 76 hours, four SPS burns were performed. Undocking of the
LM from the CSM in lunar orbit occurred'98.S hours after launch. At approxi
mately 100 hours, the first DPS maneuver, the Descent Orbit Insertion (001)
burn was performed. The burn duration was 27.4 seconds and included opera
tion at the minimum throttle setting and throttling to the 40% of full thrust
lReference 2.
4
level. This burn put the LM into a lunar orbit of 61.2 by 8.4 nautical
miles. At approximately 101 hours after launch, the OPS performed a Phasing
Maneuver burn, 39.9 seconds in duration. The spacecraft was now in a lunar
orbit of 190.1 by 11.0 nautical miles. The burn included operation at the
minimum throttle setting and a short duration segment at the Fixed Throttle
Position (FTP). The Phasing Maneuver ended the OPS mission duty cycle. The
descent stage was separated from the ascent stage about two hours later.
The APS performed two firings, the latter being to propellant depletion and
the SPS performed one more burn during the subsequent portion of the
mission.
The actual ignition and shutdown times for the two OPS firings are
shown in Table 1.
The Apollo 10 Mission utilized LM-4 which was equipped with OPS engine
SIN 1039. The engine and feed system characteristics are presented in
Table 2.
Each OPS burn was prededed with a two jet +)( LM Reaction Control
System (RCS) ullage maneuver to settle propellants.
There was one Apollo 10 Mission Detailed Test Objective (OTO) specifi
cally related to the OPS.
P13.14 LM Supercritical Helium.
The functional test objective of this OTO was:
1) Obtain data on OPS supercritical helium pressureprofile during standby and during OPS 001 and phasingburns.
The detailed requirements of this objective are described in Reference 3.
5
4. PERFORMANCE ANALYSIS
Due to the insufficient duration of the two DPS maneuvers performed
during the Apollo 10 Mission, a meaningful detailed analysis using the
Apollo Performance Analysis Program could not be made. Analysis was
further hampered by the loss of the 001 burn data. The burn was performed
behind the moon and the CSM failed to record the LM data.
Upon activating the ambient helium start bottle in preparation for
the 001 burn, DPS pressures appeared nomi na1 wi th the exception of the
oxidizer interface pressure measurement (GQ 4l11P) and the redundant
helium regulator outlet pressure measurement (GQ 3018P). At this time,
the regulator outlet pressure (GQ 3025P) and fuel interface pressure!
(GQ 36l1P) were approximately equal at 251 and 250 psia, respectively. The
oxidizer interface pressure was 241 psia while the redundant regulator
outlet pressure (GQ 3018P) was 247 psia. The chamber pressure measurement
had a bias of from 0.8 to 1.6 psia prior to the burn. Simulation of an
FTP time slice during the phasing burn indicated that the oxidizer pressure
transducer must have incurred a downward shift. Had the interface pressure
been as measured, the mean chamber pressure (with bias included) would have
been more than one psi lower than observed. It was concluded that at FTP,
the interface pressures were essentially equal and that there was a bias of
approximately 7.5 psi on the oxidizer interface transducer. Similar
reasoning,and the fact that the regul ator outlet pressure as measured by
GQ 3025P matched the predicted value during the burn. indicated that the
regulator outlet pressure measurement (GQ 30l8P) was biased low by approxi
mately 4 psi. Table 3 presents the flight measurements for the Descent
Propulsion System.
6
Descent Orbit Insertion Burn
Although the data for the DOl Burn was not recorded, indications are
that the DPS performed satisfactorily. Prior to and after the maneuver,
the system pressures appeared nominal. Astronaut reports of the burn indi
cated normal operation. The burn was initiated at the minimum throttle
setting of 13.1% of full thrust. After approximately 14 seconds, the
engine was to be manually throttled to the 40% level for the remainder of
the maneuver. The length of the burn was reported to have been approxi
mately 27.4 seconds with a measured velocity change of 70.66 ft/sec. The
actual velocity gain target was 71.25 ft/sec. The preflight performance
predicted burn time was 28.0 seconds with a simulated velocity change of
71.6 ft/sec. There are three primary reasons for the difference between
predicted and actual burn times: 1) differences in velocity gain, 2)
simulated minimum throttle setting, and 3) simulation of the throttling
transient from 13.1% to 40%. The preflight assumed minimum throttle posi
tion was 11.3% while the actual inflight setting was 13.1%. In simulating
the burn, a step change between throttle settings was assumed while the
actual maneuver requires approximately one second. If these differences
are accounted for, it appears that the predicted and the actual burn time
would differ by less than 0.1 seconds. Other uncertainties about the burn
include actual start transient, time of throttling to 40%, actual throttle
position after throttling (since the maneuver was performed manually) and
spacecraft weight errors. In view of the above, it was concluded that the
performance was nominal.
The attainment of the target velocity gain is extremely critical to the
descent trajectory. The small residual (difference between target and
actual) of 0.6 ft/sec was easily nulled by use of the LM-RCS.
7
Phasing Burn
The Phasing Burn was performed satisfactorily. The burn was initiated
at the minimum throttle setting. After 26 seconds the engine was automati
cally throttled to the Fixed Throttle Position (FTP) for the remainder of
the maneuver. System pressures appeared nominal during and after the burn.
The actual burn time was 39.94 seconds with velocity gain of 175.8 ft/sec,
while the predicted burn time was 40.3 seconds for a velocity gain of 174.5
ft/sec. The actual target velocity gain was 176.9 ft/sec. As with the
DOl Burn, the difference in predicted and actual velocity gain and time
can be essentially accounted for by the difference in the simulated and
inflight throttling transients, minimum throttle setting and start transient.
Table 4 presents the inflight measured data at typical points during each
of the two throttle positions experienced in the Phasing Burn. The pre
flight predicted values, obtained from Reference 5, are also presented for
comparison. The inflight measured data compares well with preflight pre
dicted data. Deviations at the minimum throttle setting (FS-l + 10 seconds)
are due to the difference between flight and predicted throttle setting.
Although detailed performance analysis could not be made, the flight data
was used in the prediction model ~ give an indication of approximate in
flight performance. The results are also presented in Table 4. Figure 1
through 9 present DPS inflight measured supercritical helium tank pressure,
regulator outlet pressure, interface pressures, chamber pressure and gaging
system readings during the Phasing Burn.
8
5. PRESSURIZATION SYSTEM EVALUATION
The performance of the pressurization system was considered satisfactory.
The ambient start bottle was loaded with approximately 1.1 lbm of
helium at a pressure of 1619 psia at approximately 72.5°F. At launch, the
pressure was approximately 1612 psia. Five days prior to launch, the oxi
dizer and fuel tank pressures were increased from their load pressures to
186.2 and 193.3 psia, respectively. At launch, the p~opellant tank pressures
had decreased to approximately 168 and 188 psia, respectively. Approximately
30 hours prior to launch, the supercritical helium (SHe) tank fill proced
ures were comp1eted with approximately 48 lbm of helium loaded at a pressure
of about 95 psia. At launch, the pressure had risen to approximately 316
psia. The SHe tank pressure increase during this period was approximately
7.65 psi/hr due to normal heat leak into the system from the surrounding
environment. During the 119 hour countdown demonstration test, the pres
sure rise rate was 7.31 psi/hr.
At 97.5 hours after launch, prior to pre-burn propellant tanks pressuri
zation, the ambient helium bottle pressure was 1577 psia, the SHe tank
pressure was .885 psia, the oxidizer tank pressure was 97 psia and the fuel
tank pressure was 152 psia. The pressure decay in the propellant tanks
was attributed to helium going into solution (Reference 6). The decay in
the ambient start bottle pressure was greater than expected when only
temperature effects are considered. In the case of Apollo 9/LM-3, the
start bottle pressure showed little decay during the four days prior to
launch. Indications were that the temperature in the bay where the start
bottle is located, prior to the first DPS burn, were similar to LM-3 (which
showed little start bottle pressure decay from launch to burn). It is,
9
therefore, possible that there was a small helium leak which could have
been caused by launch vibrations. An accurate analysis could not be made
due to pressure measurement inaccuracies and the lack of system temperature
measurement. Upon activation of the ambient start bottle, the pressures
increased to 248.51and 249 psia in the oxidizer and fuel tank, respectively.
Thus, although there may have been a helium leak, the ambient start bottle
performed as expected and caused no anomalies in propellant pressurization.
The average SHe tank pressure rise, from launch was approximately 5.84 psi/
hr. This flight pressure rise rate was somewhat less than anticipated
based on ground tests. Similar reductions of inflight pressure rise rate
was experienced on LM-3. Because of a known helium leak observed in the
SHe system after the first DPS burn, however, it was not clear whether the
reduced rise rate was due to zero-g coast conditions or the existence of
the leak prior to the first burn. Based on the similar pressure rise rate
experienced during the Apollo 10 Mission, it appears that the LM-3 pressure
rise was normal and that the leak occurred after system activation prior
to the first burn. In view of the above, the flight pressure rise rate to
to be used for system predictions is being revised.
From the available flight data, it appears that the SHe system operated
normally during both DPS burns.
lIncludes apparent 7.5 psi bias as discussed in Performance Analysis section.
10
6. PQGS EVALUATION AND PROPELLANT LOADING
Propellant Quantity Gaging System
At engine ignition for the second DPS burn, the oxidizer propellant
gages (Ox 1 and Ox 2) were reading off scale, as expected (greater than
the maximum 95 percent indication). The fuel tank probes (Fu 1 and Fu 2)
had readings of 94.2 and 94.5 percent, respectively. Based on the best es
timate of consumed propellant during the 001 maneuver, the fuel tank meas
urements should also have been reading off scale at ignition. This devia
tion was also noted prior to launch. After ignition, the fuel quantities
remained relatively constant for approximately 31 and 27 seconds for Fu 1
and Fu 2, respectively, at which time propellant consumption was indicated.
The oxidizer gages began to show consumption at approximately 35 and 37
seconds for Ox 1 and Ox 2, respectively. At the end of the burn, the pro
pellant gages were reading 92.4, 92.0, 93.8 and 94.5 percent for Fu 1, Fu 2,
Ox 1 and Ox 2, respectively. Table 5 presents a comparison of the measured
data and the best estimate of the actual values at the end of the Phasing
Burn. Although the Ox 2 gage is outside the specification limits of 1.3%,
it should be noted that the lack of data from the 001 burn somewhat compro
mises the calculated values. Although initially giving erroneous output,
the fuel gages appeared to be functioning within specification limits at
engine shutdown. All values were within the expected accuracties of 2.7%
and 3.5% for oxidizer and fuel (Reference 7). These accuracies were de
veloped from recent tests conducted at the White Sands Test Facility (WSTF).
The failure of the fuel gages to reach a maximum reading when greater
than that amount of propellant was in the tanks has been attributed to
either chemical reaction with alodine or aluminum impurities with the fuel,
or contamination of the fuel sensors due to the referee propellant (used
11
instead of live propellants in probe manufacture and calibration) or alodine
surface treatment (Reference 8). A chemical reaction between the fuel and
impurities, which are not clearly understood, could cause in insulating
barrier to be set up such that the conductance within the sensing portion of
the gaging system probe is reduced, thus causing a reduction in the full
scale reading. This barrier could be in the form of bubbles forming on the
inner electrode when the sensor is submersed in stagnant fuel. Asmall
quantity of residual from the referee propellant or from the alodine surface
treatment of the gage (prior to installation) could combine with the pro
pellant and form a conductive component in the fuel that settles in the
reference region at the bottom of the gaging probe causing the signal to
be low at gage activation. For either of these to happen, the propellant
would have to be in a stagnant condition. It was thus concluded in Refer
ence 8 that under zero gravity conditions, these problems should not occur,
particularly due to ReS and SPS activities which would tend to keep the
propellant reasonably active inside the tanks. In the case of this flight,
it is possible that the propellant movement prior to engine burn was not
great enough to remove contamination from the reference region.
Propellant Loading1
Prior to propellant loading a density determination was made for the
oxidizer and fuel. The analysis yielded an oxidizer density of 90.22 lbm/ft3
and a fuel density of 56.44 lbm/ft3 at a pressure of 240 psia and a temper-
1Reference 9
12
ature of 70° F. The oxidizer and fuel were loaded to their planned overfill
quantities of 11400.4 1bm and 7136.7 1bm,respectively. Off-loading was
planned such that the target loads of 11209.4 lbm of oxidizer and 7054.8 lbm
of fuel would be obtained~ During this procedure, however, 45.3 lbm more
fuel was off-loaded than planned. The actual propellant loads at launch
were 11209.2 1bm of oxidizer and 7009.5 lbm of fuel.
13
7. ENGINE TRANSIENT ANALYSIS
The mission duty cycle of the DPS during Apollo 10 included two starts
at the minimum throttle setting, one shutdown at approximately 40% throttle
and one shutdown at FTP. During the 001 Burn the engine was manually
throttled to 40% throttle and during the Phasing Burn the engine was auto
matically throttled to FTP.
Due to data loss during the DOl Burn, only the transients for the
Phasing Burn were analyzed. The transients for this burn were considered
satisfactory since they compared well with predicted values. It should be
noted, however, that the shutdown transient time was greater than the
speci fi cati on 1imit by approximately 0.09 seconds.
Phasing Burn Start and Shutdown Transients
In determining the time of engine fire switch signals (FS-l and FS-2),
the technique as developed in Reference 10 was used. This method, devel
oped from White Sands Test Facility (WSTF) test data, assumes that appro~i
mately 0.030 seconds after the engine start command (FS-l), an oscillation
in the fuel interface pressure occurs. Similarly, 0.092 seconds after the
engine shutdown signal (FS-2) another oscillation in the fuel interface
pressure occurs. Thus, start and shutdown oscillations of the fuel inter
face pressure were noted and the appropriate time lead applied.
The ignition delay from FS-l to first rise in chamber pressure was
approximately 0.85 seconds. It has been shown from past fl ights that the
first start of a duty cycle is generally longer than subsequent starts by
a factor of approximately two. This difference appears to be because of a
difference in engine priming conditions, since prior to the first start,
14
certain engine ducts are dry. Since this was the second start of the duty
cycle, the delay time appeared reasonable and compared favorably with similar
starts experienced during Apollo 5 and Apollo 9 flights.
The start transient from FS-l to 90% of the steady-state throttle
setting (13.1% of full thrust) required 2.13 seconds with a start impulse
of 728 1bf-sec. The transient time was well within the specification limit
of 4.0 seconds for a minimum throttle start. The measured impulse compared
favorably with the predicted (Reference 5) nominal value of 862 1bf-seconds
(although the nominal predicted time was approximately one second greater
than measured) as well as similar starts performed during Apollo 5. The
measured value was somewhat low when compared with DPS starts on Apollo 9.
One possible reason this deviation may be the coast time between burns.
Although there is insufficient flight data to fully correlate the effects,
it appears that the magnitude of the start impulse may be proportional to
the coast time between burns. This is due to residual propellants
freezing in the injector at engine shutdown before they can reach the
com~ustion chamber. An appreciable amount of time is required for these
propellants to sublime away. The result can be partially primed injector
at engine restart. The coast time between the burns performed on Apollo 10
was approximately 72 minutes which is less than all coast periods with the
exception of the coast between DPS 2 and DPS 3 on Apollo 5 (0.5 min). The
magnitude of the start impulse for the Phasing Burn falls between that of the
Apollo 5 DPS 3 start and the other starts from Apo1Jo 5 and Appl10 9.
The shutdown transient required 0.34 seconds from FS-2 to 10% of the
steady-state throttle setting (FTP) with an impulse of 2041 1bf-sec •. Both
the time and impulse for the transient are greater than observed during
Apollo 5, where similar shutdowns were conducted, but compares favorably
15
with the nominal predicted values of 0.32 seconds and 2017 1bf-sec. The
transient time was, however, greater than the specification limit of 0.25
seconds for shutdowns performed from FTP. There is no specification limit
on impulse. The impulse from FS-2 to zero thrust as determined by consi
deration of spacecraft weight and vehicle velocity gain was 2948 lbf-sec.
This agrees well with the predicted value of 3089 lbf-secs but is somewhat
greater than the impulse experienced on Apollo 5 shutdowns. Table 6
presents a summary of the transients.
Throttle Response
During the'Phasing Burn, the engine was automatically throttled from
the minimum throttle position to FTP. The time from first movement of the
engine actuator, to five psi less than steady-state chamber pressure at FTP
was 0.94 seconds. This was within the specification limit of 1.0 seconds.
This value is 0.6 seconds greater than a similar throttle change performed
during Apollo 5 but was similar to like throttling performed during Apollo
9 (40% to FTP in 0.82 seconds).
16
S. REFERENCES
1. TRW IOC 69.4354.2-54, "DPS Input to Apollo 10 Mission Report," fromR. l. Barrows to D. W. Vernon, dated 16 June 1969.
2. NASA/MSC Report MSC -00126, IlApoll0 10 Mission Report,1l dated Auq.1969. ' ,
3. SPD9-R-037, IlMission Requirements, SA-505/CSM-106/lM-4, F Type Mission,lunar Orbit, II dated 31 January 1969.
4. TRW letter 69.7254.3-61, "Support to the Postflight Analysis of theGN&C Sys tems on Apo110 10, II from D. L. Rue to J. F. Hanaway, dated1 July 1969.
5. TRW IOC 69.4354.2-12, IlApol10 Mission F/lM-4/DPS Preflight PerfonnanceReport," from R. K. M. Seto, D. F. Rosow, S. C. Wood and J. O. Ware toD. W. Vernon, dated 21 February 1969.
6. TRW IOC 69.4354.1-70, IllM-4 DPS Fuel Ullage Pressure Prior to FirstBurn,1l from R. L. Barrows to P. H. Janak, 6 June 1969.
7. GAEC Report lED-271-98, IlPQGS Accuracy Study,1l dated 14 May 1969.
8. Trans Sonic, Inc. Report No. 4-04003C, IlFinal Report Analysis ofStagnation (Time lag) Anomaly in Propellant Quantity Gaging Section,1ldated April, 1969.
9. SNA-8-D-027 (II!), Rev. 1, "CSM/lM Spacecraft Operational Data Book,"Vol. III, Mass Properties, dated November 1968.
10. MSC Memorandum EP22-41-69, "Transient Analysis of Apollo 9 lMDE,11 fromEP2/Systems Analysis Section to EP2/Chief, Primary Propulsion Branch,dated 5 May 1969.
17
ee
TABL
E1
DPS
MIS
SION
DUTY
CYCL
E(4
)
e
-'
00
BURN
FS-l
FS-2
BURN
DURA
TION
VELO
CITY
CHAN
GE(H
R:M
IN:S
EC)
(SEC
ONDS
)(H
R:M
IN:S
EC)
(SEC
ONDS
)(S
EC)
(FT/
SEC)
DPS
1(1
)99
:46:
00.8
935
9160
.89
99:4
6:28
.335
9188
.327
.4(2
)70
.66
DPS
2(3
)10
0:58
:25.
8936
3505
.89
100:
59:0
5.83
3635
45.8
339
.94
175.
82
(1)
Ref
eren
ce4
(2)
Ast
rona
utR
epor
ts.
(3)
Tra
nsie
ntA
naly
sis
(4)
Ref
eren
ced
toG
roun
dE
laps
edTi
me
(GET
)
------ -----
TABLE 2
LM-4 DPS ENGINE AND FEED SYSTEM
PHYSICAL CHARACTERISTICS
ENGINE
Resistance,
Engine Number
Chamber Throat Area, In2
Nozzle Exit Area, In2
Nozzle Expansion Ratio
Oxidizer Interface To Chamber
Resistance at FTP lbm-sec2
lbf-ft S
Fuel Interface To Chamber
Resistance At FTP lbm-sec2
lbf-ft S
FEED SYSTEM
Oxidizer Propellant Tanks, Total
Ambient Volume, Ft 3
Fuel Propellant Tanks, Total
Ambient Volume, Ft 3
Oxidizer Tank To Interface
lbm...sec2
lbf-ftS
Fuel Tank To Interface
lbm-sec2Resistance, lbf-ftS
1039
53.740 1
2569.7 4
47.64
6207.9
126.0
126.04
496.n2
757.682
1 TRW No. 01827-6l25-TOOO, TRW LM Descent Engine Serial No. 1039Acceptance Test Performance Report Paragraph 6.9, 8 December 1967.
2 GAEC Cold Flow Tests
3 TRW No. 4721.3.68T188, LM-4, Engine Serial No. 1039 Descent EngineCharacteristic Equations, July 1968.
4 Approximate Values
19
MEASUREMENTNUMBER
GQ3435P
GQ3015P
GQ3018P
GQ3025P
GQ3611P
GQ411lP
GQ6510P
GQ3603Q
GQ3604Q
_Q4103Q
GQ4l04Q
GQ4455X
GQ3718T
GQ3719T
GQ4218T
GQ4219T
GQ6806H
GH131lV
GH1331V
GGOOOlX
TABLE 3
DESCENT PROPULSION SYSTEM FLIGHT DATA
DESCRIPTION RANGE
Pressure, Supercritical Helium Tank 0-2000 psia
Pressure, Ambient Helium Bottle 0-1750 psia
Pressure, Helium Regulator Outlet Mani-fold 0-300 psia
Pressure, Helium Regulator Outlet Mani- 0-300 psiafold
Pressure, Engine Fuel Interface 0-300 psia
Pressure, Engine Oxidizer Interface 0-300 psia
Pressure, Engine Thrust Chamber 0-200 psia
Quantity, Fuel Tank No. 1 0-95 percent
Quantity, Fuel Tank No. 2 0-95 percent
Quantity, Oxidizer Tank No. 1 0-95 percent
Quantity, Oxidizer Tank No. 2 0-95 percent
Low Point Senso~ Propellant TanksLiquid Level Off-On
Temperature, Fuel Bulk Tank No. 1 20-l20°F
Temperature, Fuel Bulk Tank No. 2 20-120°F
Temperature, 9xidi~e~ Bulk Tank No. 1 20-120°F
Temperature, Oxidizer Bulk Tank No. 2 20-120°F
Position, Variable Injector Actuator 0-100 percent
Volts, Manual Thrust Command 0-14.6 VDC
Volts, Auto Thrust Command 0-12 VDC
PGNS Downlink Data 40 Bits
20
SAMPLE RATESAMPLE/SEC
1
1
1
1
200
200
200
1
1
1
1
1
1
1
1
1
50
1
10
1/2
ee TA
BLE
4
DESC
ENT
PROP
ULSI
ONSY
STEM
STEA
DYST
ATE
PERF
ORM
ANCE
PHAS
ING
BURN
e
N ......
PARA
MET
ERFS
-l+
10Se
cond
sI
FS-2
+35
Seco
nds
Pre
flig
htM
easu
red
Po
stfl
lgh
tP
refl
lgn
tM
easu
red
Po~tflig
ht_
Inst
rLlll
ente
dP
redi
cted
Pred
icte
dP
redi
cted
Pre
dict
ed
Thr
ottl
eP
osit
ion,
%11
.313
.113
.1FT
PFT
PFT
P
Reg
ulat
orO
utle
tP
ress
ure,
psia
247
247
247
247
247
247
Oxi
dize
rIn
terf
ace
243
122
51P
ress
ure,
psia
243.
724
3.0
224.
622
5.0
Fuel
Inte
rfac
eP
ress
ure,
psia
243.
624
324
3.0
224.
922
522
5.0
Eng
ine
Cha
mbe
rP
ress
-14
.810
5.9
ure,
psia
12.7
1410
610
5.9
Oxi
dize
rB
ulk
Tem
p-~rature,
OF70
.069
69.0
70.0
6969
.0
Fuel
Bul
kTe
mp.
,OF
70.0
7070
.070
.0]0
70~0
Der
ived
Oxi
dize
rF
low
rate
,lb
m/s
ec2.
442.
8519
.87
19.9
2
"'uel
Flo
wra
te,
lbm
/sec
1.53
1.77
12.5
112
.46
Pro
pell
ant
Mix
ture
Rat
io1.
601
1.60
51.
589
1.59
9
Vac
uum
Spe
cifi
cIm
-pu
lse,
sec
296.
7929
6.48
303.
6430
3.98
Vac
uum
Thr
ust,
lbf
1181 1
1371
9831
9841
~hroat
Ero
sion
,%
0.99
30.
993
0.99
40.
994
lThe
seva
lues
corr
ecte
din
acco
rdan
cew
ithte
xt.
TABLE 5DPS GAGING SYSTEM PERFORMANCE
END OF PHASING BURN
PARAMETER
Oxi di zer Tank 1Measured Quantity, percentCalculated quantity, percentDifference, percent
Oxi di zer Tank 2Measured quantity, percentCalculated quantity, percentDifference, percent
Fuel Tank 1Measured Quantity, percentCalculated quantity, percentDifference, percent
Fuel Tank 2Measured quantity, percentCalculated quantity, percentDifference, percent
22
Time. hr:min:sec100:59:06
93.8
92.9+0.9
94.592.9+1.6
92.492.7
-0.3
92.0
92.7-0.7
eILE
6
DPS
STAR
TAN
DSH
UTDO
WN
IMPU
LSE
SUMM
ARY
e
N W
Apo
llo10
IApo
llo5
Apo
llo5
Apo
llo9
Apo
llo9
Apo
llo9
SPEC
IFIC
ATIO
NM
-4/D
PS-2
LM-1
/DPS
-2LM
-1/D
PS-3
L~1-3/DPS-1
LM-3
/DPS
-2U~-3/DPS-3
LIM
ITS
STAR
TSS
tead
y-S
tate
Thr
ottl
eP
osit
ion,
Per
cent
13.1
12.4
12.4
12.7
12.7
12.7
Tot
a1V
acuu
mS
tart
Impu
1se
(FS-
1to
90%
stea
dyst
ate)
,1b
f-se
c72
889
457
480
510
2995
0
~tart
Tim
e(F
S-1
to90
%st
eady
stat
e),
2.13
2.66
2.13
2.51
2.1
2.3
14.
0Is
ec.
lCoa
stTi
me
From
Pri
or
Bur
n,M
inut
es72
131
0.5
From
Laun
ch26
4011
1
SHUT
DOW
NS~teady-State
Thr
ottl
eP
osit
ion,
perc
ent
FTP
FTP
FTP
4040
12.7
~otal
Vacu
umS
hut-
~own
Impu
lse-
(FS-
2~o
10%
Stea
dyS
tate
),2
1bf-
sec
2041
1727
1713
---17
3074
8
~hutdown
Tim
e(F
S-1
~o
90%
stea
dy
-sta
te),
1.11
1.81
0.25
4lie
c0.
340.
260.
301.
1
Rep
eata
bili
ty,
1bf-
sec
1734
+717
34+7
+100
4
otal
Vac
uum
Shut
dow
nIm
puls
e(F
S-2
toZ
ero
~hrust)
from
Vel
ocit
y3
1777
210
40~ain
Dat
a,lb
f-se
c29
4824
93--
---
-
1Ref
eren
ce10
.
2 Dat
a_u
nava
ilab
le.
3Una
vaila
b1e
due
toAP
SIF
ire-
in-t
he-H
o1e"
man
euve
r
4Spe
cifi
cati
onva
lue
for
shut
dow
nspe
rfor
med
from
FTP
only
.
c:( ..... V)
0... I
~ :if J--
~ ..... ...J w
0..
:cl!
lC
")..
.Jq
-N
c:(
C"'
)~
L>
CY
.....~
J-- ..... a: u a: l.LI
0..
=:l
V)
l.LI
a: =:l
V)
V)
l.LI
a: Q,.
• o q- .....
.....-
o N r .....-
o co o .....-
o q- o .....- IG
NIT
ION
o o o
eAP
OLLO
10SC
106/
LM4
-DP
Se
FIGU
RE1
SUPE
RCRI
TICA
LHE
LIUM
TANK
PRES
SURE
PHAS
ING
BURN
SHUT
DOW
N
3635
0536
3510
3635
1536
3520
3635
2536
3530
3635
3536
3540
3635
4536
3550
GROU
NDEL
APSE
DTI
ME
(SEC
)
e
e
8•M
oo·o~
oo·o~
8ci-Q..N
CD-otT)o
8~·51--cr-en
0-_CJ
o~...J5l0_LL-Zcr2:0
o~.
'::)~0-
t.!)
~UJ8~.
SI•
enenLu~oQ..o
~
APOLLO 10 SC106/LM4-DPS-(RAW DATRl
----...___________________ GO,3018P
FIGURE 2
MEASURED HELIUM REGULATOROUTLET PRESSURE
PHASING BURN
0aa('n
eC)cci363490 363495 363500
IGNITION
363505 363510 263515 36352Q 363525 363530GROUND ELLAPSED TIME (SEC)
363535 363540
SHUTDOWN
363545 363550 363555 36356025
; APOLLO 10 SC106/LMij-DPS-(RRW DRTRl
e 8•~
aa•a
CDcot
363555 36356026
, GQijll1P
363550_
FIGURE 3
MEASURED OXIDIZERINTERFACE PRESSURE
PHASING BURN
363545363540363535363515 _ 363520_~ 363525 363530GROUND ELAPSED TIME (SEC) I
363510363505363500363495
8•
8 , I
363490 I I I I I I I I ; II I I Iii
aa•a
iCQ..--~SJi.-a:-(f)oQ..O
e 8iX0
~8a: •"-80:-IAJ~Z-IAJ~~c.!)-Zl&J
cii8en •~a:-«L
aa·0
"- I
IGNITION SHUTDOWN
e
;_ APOLLO 10 SC10S/LMij-DPS-(RAW DATAl
e 8~
8·i
e
8Q..R......~~...:1a::....entL
:38~
II • • ....._,.GC3611 P
LLJU
Ifsa: •~z.....lIJ~8~ffi-(I)en
~tLa•-
FIGURE 4MEASURED FUEL
INTERFACE PRESSUREPHASING BURN
36356036355527
SHUTDOWN
363545 363550363540363535363515 363520 363525 363530GROUND ELAPSED TIME, (SEC)
IGNITION
363505 363510363500363495
8•! I i I I ' I363490 I iii ii' I ,
, .
8•
R-e
; APOLLO 10 SC106/LM4-DPS-lRAW DATAl
e 8·:it-aQ,i1-8•9-
e
@s~8lJ') •tOog~
•-a:-0ena0-0-au:LLJCD2:a::r:au~
1-1en::Ja:::I:1-
8. .enQ
cnCD
~0-
FIGURE 5
MEASURED CHAMBER PRESSUREPHASING BURN
8·~
SHUTDOWNIGNITION
c:::aa -I ." , , ',.w: I . I L - -...,d I I' iii i • Ii" :+ i .Ga6510P363490 363495 363500 363505 363510 363515 363520_ 363525 363530 ' 363535 363540 363545 363550 363555 363560
GROUND ELAPSED TIME, (SEC) 28
8,aN
e